EP1371999A1 - Method and system for tracking a target - Google Patents

Abstract

The method involves searching a search space in several passes at a first clock rate to determine target track information, extrapolating an anticipated flight path from at least two passes, sending flight path data at a higher clock rate to a tracking sensor, aligning the tracking sensor with a tracking space when the target reaches the space independently of detectability, determining when the target is detectable and automatically tracking. The method involves searching a search space with a search sensor (12) in several passes at a first clock rate to determine target information describing a track (4) on which a target (2) is flying, extrapolating an anticipated flight path (6) from the information from at least two passes, sending flight path data at a higher clock rate to a tracking sensor (14) covering a tracking space (15), aligning the tracking sensor with the tracking space when the target reaches the space but independently of target detectability, determining when the target is detectable and automatically following the target with the tracking sensor. An Independent claim is also included for a target following system.

Description

The invention relates to a method for pursuing a goal according to the Claim 1 and a tracking system according to claim 11.

The invention is particularly, but not exclusively, in Relation to the pursuit of flying targets to combat are realized.

Conventionally, a search sensor and a follow sensor are used used. The search sensor covering a search space is in particular for this purpose determines to search its search space for a target within it and to determine target information, which at least the movement of the Describe the goal or the track of the goal in the past. Most of the time, the target information contains more information about the target, especially about the type of goal. In general, it is appropriate to To design the search sensor so that it has a long range and a large range Angular range, that is to say active and detailed in a wide search area Can provide target information. Search sensors usually work with relatively low ones Search clock rates. From the data determined by the search sensor then extrapolative trajectory data determined which the expected Describe the movement of the target in the future. This trajectory data will be essentially used to carry out a rough straightening of the following sensor. The follow sensor is often designed in such a way that it covers a follow room that is more restricted than the search space of the search sensor. The follow sensor must after taking over the target from the search sensor, in an initial phase of his Activity, seek the target again before capturing the target, focus on the target align and follow the goal.

A disadvantage of this conventional method is that the The takeover of the target by the subsequent sensor was not easy. Especially The problems are serious if the subsequent sensor is worse Visual characteristics and / or a noticeably smaller field of view and / or one has a different range than the search sensor. Another disadvantage is that the search clock rate of the search sensor, which is at least partially the Process flow determined, and with which the target trajectory data for the Follow sensor provided, is relatively low, but an increase the search clock rate cannot be achieved with reasonable effort.

No. 5,379,676 describes a method and a system for a Fire control system of a manually adjustable weapon has become known. Intended is a sensor system with a radar device and an electro-optical one Detection system in the form of a FLIR camera. This procedure and this Systems are comparatively complex to build, but the ones achieved with them However, results are not satisfactory.

• ein verbessertes Verfahren der eingangs genannten Art vorzuschlagen; und
• ein Zielverfolgungssystem zur Durchführung dieses Verfahrens zu schaffen, mit welchen die Nachteile des Standes der Technik vermieden werden.

It is therefore an object of the invention

• to propose an improved process of the type mentioned at the beginning; and
• to create a target tracking system for performing this method which avoids the disadvantages of the prior art.

• für das Verfahren durch die Merkmale des Anspruchs 1; und
• für das Zielverfolgungssystem durch die Merkmale des Anspruchs 11.

This object is achieved according to the invention

• for the method by the features of claim 1; and
• for the target tracking system by the features of claim 11.

Preferred developments of the invention are given by the respective dependent claims 2 to 10 and 12 to 30 defined.

The new procedure works as follows: The search sensor searches, as with the conventional method, its search space for a target. The Search space in several search runs at a first clock rate or search clock rate searched. The search clock rate does not have to be here be exactly constant. The search sensor determines from its perspective an image sequence, the time interval between the images of an image sequence by the first clock rate or search clock rate is determined. Below pictures are in to understand digital images in this context. With rotating Search sensors corresponds to the first clock rate or search clock rate in Generally the number of search sensor rotations per unit of time. Is located a target in the search space, the search sensor determines in its search clock rate several successive searches, respectively Search sensor rotations target information. Describe the target information if necessary using interpolations that have already passed through the target Track. The target information can also provide more details about the target included, for example information about the target type or results of a Friend / foe query, through which captured targets as objects to be combated, So actual targets, or qualified as friendly missiles. In Knowledge of the target information from several searches, but if necessary. only using the target information regarding enemy targets an expected trajectory or trajectory data by extrapolation provided which describe the trajectory that the target is believed to be in the Future will follow. Instead of directly aiming as in the conventional method take over, in the beginning to search for the goal again and autonomously follow, the new procedure follows during a transition phase of Follow sensor not self-sufficient but externally controlled. The external control takes place on the basis of the trajectory data that the following sensor in a second Clock rate that is higher than the first clock rate or search clock rate. During the transition phase, the externally controlled follow sensor aligned to the expected trajectory, namely even if the destination is in the next room, but from Follow sensor is not yet sensible. As soon as the target is sensible, it will be Follow sensor detected, whereby the transition phase or External control of the following sensor has ended. The next sensor will be used from now on track the target autonomously or follow the target independently. While in the transition phase, the goal is not directly through the follow sensor sensible, but the follow sensor still follows, in a way that is 'blind' can be referred to, the goal, at least approximately within the framework of possible accuracy, which is determined, among other things, by extrapolation. A renewed search for the target, this time by the follow sensor, is unnecessary yourself. The follow sensor is at the moment when the target can be sensed directly through it is already aimed at the goal. In practice, a target point is mostly on which the following sensor is aligned, and the target point environment using a Visualization unit (e.g. in the form of a monitor), where Usually an arrangement is chosen in which the target point is the Occupies the center of the monitor. With the new method, the target appears when it is is directly sensible by the following sensor, in the immediate vicinity of the Target point (or within a gate displayed on the monitor); the target would appear exactly at the target point if the actual Trajectory would coincide with the extrapolated trajectory and also otherwise you would not notice any uncompensated errors. to intra-system transfer of related to the new procedure used data, the target tracking system has the usual appropriate Transfer agents. In addition, it should be noted that the respective data of course continuously or in cycles taking into account the respective latest target information will be updated.

The advantages achieved with the invention are essentially those Following: An operator at the following sensor does not have to be manual Carry out search movements still trigger automatic search movements, as long as no target appears on the monitor of the following sensor; Reasons, that no goal appears can be the following: the goal is not yet in the Next room or too small; the goal is in the next room but View of the target is covered or not due to atmospheric absorption recognizable. At the latest when the target reaches the follow room, follow sensor acts, with the help of the external control, as if he were to capture the target, although he is target blind; the following sensor can possibly also on the target or the suspected trajectory are aligned before the target reaches the next room. In any case, the acquisition of the target is ensured if the Search sensor has found a target. So the surgeon can rely on it focus, the end of the transition phase and thus the appearance of the Wait for the target on the monitor to then optically / manually or automatically follow the target to the target. Even after a long one 'Blind' target tracking can then be done directly from the next sensor Sensible target can be pursued quickly and, if necessary, combated quickly, in any case significantly faster than with the conventional use of trajectory data, which only in the low first clock rate or search clock rate were provided.

It is for trouble-free and efficient implementation of the new Procedure does not require that the search sensor and the following sensor are the same or have specifically matched search characteristics. This has the advantage that different sensors, for example from different weapon systems, can be used together by making one efficient-acting sensor network can be coupled, making the value of each Target combat sensors increased. This is particularly advantageous because the follow-up sensors are often components of existing ones Weapon systems are, their efficiency through interaction with search sensors can be increased.

In particular, the search sensor and the following sensor can be unequal Have ranges and / or cover unequal wide angular spaces, whereby in general the search sensor has a longer range and usually also can search another angular space.

In certain cases it can be advantageous to use a search sensor several different capabilities of search sensor units provide; the search sensor units can, for example, be used for different but generally overlapping partial search spaces are responsible, or you can search for the same search space but with a different view or perspective Detection relationships are responsible; this does not include only different conditions in the space between sensor and target but also different properties of the target that lead to different Lead detection results.

A radar sensor is often used as a search sensor and as a follow-up sensor For example an infrared sensor, preferably a FLIR sensor, or a TV camera or an optical line of sight.

The follow sensor is preferably designed so that it is complete regardless of the direct comprehensibility of the target by himself can be automatically aligned to the target, if necessary, even if this is still is not in the room that can be sensed by the following sensor.

The tracking means of the following sensor can be used for manual or automatic tracking of the following sensor. Are advantageous Follow sensors that can be tracked both automatically and manually, so a failure of the automatic tracking does not mean the failure of the whole Follow sensor caused.

The new method is particularly suitable in cases where the Follow sensor spatially separated from the search sensor, but of course in one known relative position to the search sensor is arranged. To achieve more precise Results, the relative position must be included in the calculations. Often, but not necessarily, search sensors are local and Follow sensors mobile. Search sensors can be components of complex Localized early warning systems form components, while follow-up sensors Of often non-localized fire control devices or weapon carriers from Can form weapon systems.

The search sensor can be used to determine the relative positions and / or the follow sensor can be equipped with appropriate search means.

The means of calculation, which are in connection with the implementation the procedure may be required by individual calculation units be educated. Such calculation units can be used by the search sensor as well be assigned to the following sensor. Generally both Search sensor as well as the following sensor and often also additional systems such as Weapon carriers via specifically designed calculation units.

In many cases, the tracking system has only one search sensor, but more than one follow sensor. There is another follow sensor in a different relative position to the search sensor than the first-mentioned subsequent sensor, see above additional trajectory data must be provided for the further follow-up sensor take into account the other relative position of the subsequent sensor.

With the help of means of communication, trajectory data or transfer additional procedural essentials to an additional system become. The additional system can, for example, a weapon carrier, in particular a gun or a rocket launcher. The weapon carrier can also be mobile his. Gun barrels are often used by guns or the corresponding servos controlled with the help of follow sensors. The weapon bearers shoot projectiles referred to as weapons in this context, which, often in fragments, should hit the target. The data must be the Take into account the relative position of the weapon carrier to the following sensor, and it must a reserve calculation to control the weapon barrel is carried out in particular the flight behavior or the ballistics of the projectiles considered.

In a particularly advantageous embodiment, the search sensor can also Be trained to receive target information from not just one person can determine multiple goals. The target information, the different Goals are then determined with the help of the calculation means that are necessary for this have specific intelligence, used and for different follow-up sensors provided.

It is common for the follow sensors to have filter media and it is a particular advantage of the invention that such filters taking into account the Trajectory data can be preset.

In practice, it is inevitable that the new target tracking system will train that when implementing the new process none system-related time delays occur. To avoid mistakes that caused by such time delays, it is advantageous to Perform calculations taking into account the time delays so that a compensation takes place in order to track the following sensor in to perform more precisely.

Fig. 1

ein erstes Zielverfolgungssystem nach der Erfindung, in einer schematischen Darstellung, welche auch die Durchführung des Verfahrens nach der Erfindung darstellt; und

Fig. 2

ein zweites Zielverfolgungssystem nach der Erfindung, mit welchem Zusatzsysteme gekoppelt sind.

Further details and advantages of the invention are described below using an exemplary embodiment and with reference to the drawing. It shows:

Fig. 1

a first target tracking system according to the invention, in a schematic representation, which also represents the implementation of the method according to the invention; and

Fig. 2

a second target tracking system according to the invention, with which additional systems are coupled.

In Fig. 1, a target 2 moving in an air space is one Time T5 shown at a location Z5. Target 2 already has a lane 4 fly through. Due to an extrapolation based on track 4, expects the target 4 to continue on a trajectory 6, shown in dotted lines will fly.

The goal 2 is achieved with the help of a tracking system 10 according to the Invention pursued. The target tracking system 10 has a search sensor 12, a follow sensor 14, calculation means 16 and transmission means 18. The Search sensor 12 covers a wide search space, the limitation of which is not is shown. The follow sensor 14 covers a follow room 15.

The search sensor 12, which in the present case has a search radar and is rotating, searches its search space in a variety of passes or rotations that follow each other at time intervals ΔT1 do not have to be constant, and that of a first or search clock rate of 2π / ΔT1, which also does not have to be constant.

The follow sensor 14 is locally separated with a storage d from Search sensor 12 arranged. The vectorial storage d of the subsequent sensor 14 from Search sensor 12 and thus also the relative position of the following sensor 14 for Search sensor 12 are known. The search sensor 12 is also a Visualization unit 22 and the follow sensor 14 a visualization unit 24 assigned.

The calculation means 16 comprise a first calculation unit 16.1, which is assigned to the search sensor 12, and a second calculation unit 16.2, which is assigned to the following sensor 14.

The transmission means 18 serve for the system-internal transmission of Data, in particular between the search sensor 12, the calculation units 16.1, 16.2 of the calculation means 16 and the follow sensor 14. Die Transmission means can be conductor-bound and / or conductor-free Include transmission units.

It should also be mentioned that dashed lines between the search sensor 12 and the track 4 and between the follow sensor 14 and the trajectory 6 symbolize sense of the target 2 while the dash-dotted lines between the follow sensor 14 and the flight path 6, the respective orientation of the symbolize externally controlled sequence sensor 14 in the transition phase.

At a time T1, the search sensor 12 had the target 2 at the location Z1 located. Thereupon goal 2 became at time T2 at Z2, at time T3 at Z3 and located at time T4 at Z4. Target 2 is at time T5, as already described, at Z5. At each of the times Z1 to Z5 were or target information is determined by the search sensor 12. This Basically, target information describes, strictly speaking, interpolated, lane 4. extrapolate from the determined target information Calculation means 16 or the expected trajectory 6 or Trajectory data ready this expected trajectory 6 in the range between Z5 and describe Z6.

The trajectory 6 is extrapolated by the calculation means 16, and the corresponding trajectory data are obtained using the transmission means 18 transmitted to the following sensor 14 or made available for this.

The trajectory 6 can be extrapolated by means of the calculation unit 16.1 or by means of the calculation unit 16.2; the extrapolation takes place the flight path 6 and only by the calculation means 16.2, so the data transmitted by the transmission means 18 at a clock rate transmitted, which is the same as the search clock rate 2π / ΔT1; the means of transmission 18 are thus less burdened than when transferring data in one second clock rate 2π / ΔT2, which is higher than the search clock rate 2π / ΔT1, in which the trajectory data is provided according to the invention for the follow sensor 14 become.

The higher clock rate corresponds to a time interval ΔT2 that is only one Fraction of the time interval is ΔT1. 1 is the Relation of the time intervals ΔT1 / ΔT2 at four; this relation of time intervals and hence the inverse relation of the clock rates is only chosen to the drawing to be organized clearly.

The trajectory 6 shows the expected movement of the target after Time T5. In the time interval between the time T5 and the time T6 target 2, starting from Z5, is expected to migrate to Z6 Time Ta, Tb and Tc at least approximately at Za and Zb or Zc can be expected. The starts at time T5 Transition phase; the target 2 has one that can be covered by the following sensor 14 Follow room 15 reached, but can not yet be sensed by the follow sensor 14 or be recorded. Therefore, it is impossible for the follow sensor 14 the target 2 is tracked independently or follows the goal 2 independently.

There are numerous reasons why the follow sensor 14 does not target 2 can record, although it is undoubtedly in the following room 15; to the For example, the target 2 may be too small or due to an obstacle, in FIG. 1 only for example represented as cloud C, covered, or the light or Atmospheric conditions do not allow the target 2 from the following sensor 14 is sensible. The follow sensor 14 is, according to the invention, during the Transition phase using the trajectory data externally controlled, whereby he by means of its alignment means to the respective place where As expected, target 2 is currently located. As a result, the following sensor 14 able to follow target 2 to some extent, blindly. To the Time Ta and Tb is the next sensor on points Za and Zb, respectively where target 2 is currently located, even though target 2 covered by the cloud C and is not visible to the following sensor 14. in the At time Tc, target 2 is then at point Zc and cloud C forms no more obstruction between the following sensor 14 and the target 2. Die Transitional phase, in which goal 2 was externally controlled, ends as soon as that Target 2 has reached the place Z * at time T *. The goal 2 can now by Detection means of the follow sensor 14 are detected and the tracking means guide the follow sensor 14 to the target 2, in other words, the Follow sensor 14 now follows target 2 independently.

Appears on the visualization unit 24 of the following sensor 14 Time T * the target 2, more precisely an image 2 'of the target 2, in a target point that is formed by the origo of a coordinate network; here is however assumed that from target 2 after time T5 actually traversed trajectory coincides with the extrapolated trajectory 6, and that the process as a whole runs ideally or that there are any errors compensate. Does the tracking of the follow sensor 14 run from the time T * ideal, the image 2 'of the target 2 always remains in the target point or at the origin of the coordinate network. Would the following sensor 14 target 2 from If time T * is not updated, image 2 'of target 2 would be along Image 6 'of trajectory 6 migrate, as is also shown in Fig. 1. It would also be possible to create fictitious images of target 2 or target marks to show the actual location Z5 of destination 2 at time T5 and the expected locations of Za and Zb of target 2 at times Ta and Play Tb; with such target marks Y5, Ya and Yb it would not be about Images 2 'or images of target 2 but a fiction act.

The visualization unit 22 of the search sensor 12 shows the track 4 of FIG Past and the expected trajectory 6 of target 2.

Fig. 2 shows a second tracking system 10 according to the invention, with a search sensor 12, which is designed not only from the target 2 but also to determine 102 target information from a second target. Goals 2 and 102 are shown on their tracks 4 and 104, respectively. The calculation unit 16.1 is trained to assign goals 2 and 102 for follow-up, where they target 2 follow sensor 14 and target 102 another follow sensor 114 assigned. If there is no second goal, the only goal can be two Follow sensors 14, 114 are assigned. The target tracking system 10 points in addition to the calculation unit 16.2, another, the further following sensor 114 assigned calculation unit 116.2. The follow sensor 14 has one Follow area 15 and the follow sensor 114 a follow area 115, which are partially overlap. With the follow sensor 14 are over Communication means 28 two additional systems 30, 31 coupled, respectively are with the follow sensor 114 via communication means 128 additional systems 130, 131 coupled. The additional systems are generally weapon carriers, with whose weapons or projectiles P are to be used against targets 2, 102. It can also be said that the follow sensors 14 and 114 together with their associated additional systems 30, 31 and 130, 131 two Form weapon systems 1 and 100 respectively.

The following part of the description is simplified and summarized Process and system specific described with reference to FIG. 1 Details of the invention also apply to FIG. 2.

Target 2 was assigned to follow sensor 14 and has time T5 reached the following room 15; in the transition phase until time T * follows the following sensor 14 is remote-controlled and 'blind' to the target 2 until the target 2 at Z * can be sensed by the subsequent sensor 14 and can then be tracked independently. In one Time T7 has the destination 2 the location Z7 and thus one to combat it reached favorable space. At a time T8, destination 2 becomes location Z8 achieved. The projectiles P based on a customary reserve calculation, at time P7 shot down, but not on location P7 but on location P8, where in At time T8, target 2 meets projectiles P. The trajectory 6 therefore ends at Z8.

The second target 102 was assigned to the follow sensor 114 and has in Time T105 reached the following room 115; in a transition phase until At time T **, the following sensor 114 follows the second destination in a remote-controlled and "blind" manner 102 until the second target 102 can be sensed by the follow sensor 114 and can then be followed independently. The second target 102 is then like in an analogous manner target 2, but fought by the projectiles of auxiliary systems 130, 131. Trajectory 106 ends at Z108.

Claims (30)

Method for tracking a target (2) moving in an air space, wherein with the aid of a search sensor (12), a search space is searched in several passes at a first clock rate (2π / ΔT1) and target information is determined which describes a track (4) traversed by the target (2), with the aid of calculation means (16) extrapolates an expected trajectory (6) from the determined target information of at least two passes and, for a follow sensor (14) which covers a follow space (15), trajectory data which the expected trajectory (8 ) describe, be provided, with the aid of transmission means (18) the trajectory data, which describe the extrapolated expected trajectory (8), are transmitted to the following sensor (14) at a second clock rate (2π / ΔT2), which is higher than the first clock rate (2π / ΔT1), and when the destination (2) reaches the next room (15), with the aid of alignment means, the following sensor (14) is aligned with the expected flight path (6) on the basis of the transmitted trajectory data, regardless of the detectability of the target (2), with the aid of detection means, the target (2) is detected as soon as it can be detected by the following sensor (14), and the tracking sensor (14) is tracked independently with the aid of tracking means. The method of claim 1, wherein
the search sensor (12) and the follow sensor (14) have different search characteristics. Method according to one of claims 1 to 2, wherein the following sensor (14) is arranged spatially separated from the search sensor (12) in a known position relative to the search sensor (12), and the calculation of the trajectory data is carried out taking into account the known relative position of the follow sensor (14) to the search sensor (12). Method according to one of claims 1 to 3, wherein
Processing of data is carried out at least in part by a calculation unit (16.1) assigned to the search sensor (12) or by a calculation unit (16.2) of the calculation means (16) assigned to the following sensor (14). Method according to one of claims 1 to 4, wherein
the relative position of the follow sensor (14) to the search sensor (12) is determined with the aid of search means which are assigned to the search sensor (12) and / or the follow sensor (14). Method according to one of claims 1 to 5, wherein with the aid of the calculation means (16), further flight path data for a further follow-up sensor (114) can be calculated, and the further trajectory data are transmitted to the further follow sensor (114) with the aid of the transmission means. Method according to one of claims 1 to 6, wherein
a communication system (28, 128) is used to transmit the trajectory data or data based on the trajectory data to an additional system (30, 31; 130, 131). Method according to one of claims 1 to 7, wherein with the aid of the search sensor (12), the search area is searched for a second destination (102) and second destination information is determined which describes a second lane (104) traversed by the second destination, with the aid of the calculation means (16), expected second flight path data (106) are made available for use by at least one following sensor (114) and at least one additional system (130, 131). Method according to one of claims 1 to 8, wherein
Filter means of the following sensor (14) can be preset taking into account the trajectory data. Method according to one of claims 1 to 9, wherein
the flight path data is calculated taking into account system-related time delays. Target tracking system (10) for tracking a target (2) moving in an air space, with a search sensor (12), which is designed to search a search space in several passes with a first clock rate (2π / ΔT1), and with a follow sensor (14), which is designed to follow the target (2) in a follow room (15), wherein the search sensor (12) has: first detection means, which are designed to detect at least some of the passes target information which describes a track (4) traversed by the target (2); the target tracking system (10) has: Calculation means (16, 16.1, 16.2), which are designed to extrapolate from the target information an expected trajectory (6) of the target (2) and to calculate trajectory data that describe the expected trajectory (6) and Transmission means (18) which are designed to transmit at least the target information-containing data to the calculation means (16, 16.1, 16.2) and at least the trajectory data, which describe the extrapolated trajectory, to the following sensor (14) in order to to provide the trajectory data for the following sensor (14) at a second clock rate (2π / ΔT2) which is higher than the first clock rate (2π / ΔT1); and where the following sensor (12) has: Alignment means which are designed to align the follow sensor (12) to the expected flight path (6) on the basis of the flight path data provided and regardless of the detectability of the target (2), second detection means, which are designed to detect the target (2) as soon as it reaches the following space (15) and can be detected, and Tracking means which are designed to autonomously track the following sensor (12) to the detected target (2) as soon as it is detected by the detection means. The tracking system (10) of claim 11, wherein
the search sensor (12) and the follow sensor (14) have different search characteristics. A tracking system (10) according to any one of claims 11 to 12, wherein the search sensor (12) has a search characteristic with a larger one Range as the following sensor (14). A tracking system (10) according to any one of claims 11 to 13, wherein the search sensor (12) has a search characteristic with a search space has, which is wider than the following room (15) of the following sensor (14). A tracking system (10) according to any one of claims 1 to 14, wherein the search sensor (12) has a plurality of search units. A tracking system (10) according to any one of claims 11 to 15, wherein the search sensor (12) has at least one radar sensor. A tracking system (10) according to any one of claims 11 to 16, wherein the detection means of the search sensor (12) are designed to the target information to capture a trace of the target (2) in space. A tracking system (10) according to any one of claims 11 to 17, wherein the following sensor (14) is an infrared sensor, preferably a FLIR sensor is. The tracking system (10) of any of claims 11-18, wherein the following sensor (14) is designed such that it is aligned by the alignment means automatically regardless of the automatic detection of the target (2) can be aligned to the expected trajectory (6). A tracking system (10) according to any one of claims 11 to 19, wherein the tracking means for self-sufficient tracking of the following sensor (14) manual and / or automatic tracking of the follow sensor (14) are trained. The tracking system (10) of any one of claims 11 to 20, wherein the following sensor (14) is independent of location. A tracking system (10) according to any one of claims 11 to 21, wherein the following sensor (14) is arranged locally separated from the search sensor (12) and in a known position relative to the search sensor (12), and the calculation means (16) are designed to calculate the trajectory data taking into account the relative position. The tracking system (10) of any one of claims 11 to 22, wherein to determine the relative position of the following sensor (14) to the search sensor (12) the search sensor (12) and / or the follow sensor (14) search means have. A tracking system (10) according to any one of claims 11 to 23, wherein at least part of the calculation means (16) for the search sensor (12) or the calculation unit (16.1, 16.2) form. The tracking system (10) of any of claims 11 to 24, wherein the calculation means (16) are designed to calculate further trajectory data for at least one further follow sensor (114), and the transmission means are designed to transmit the further trajectory data to the further sequence sensor (114). Target tracking system (10) according to any one of claims 11 to 25, wherein the follow sensor (14, 114) comprises communication means (28; 128) which enable transmission of the trajectory data to at least one additional system (30, 31; 130, 131), in which the relative position of the at least one additional system (30, 31; 130, 131) to the search sensor (12) or to the subsequent sensor (14; 114) is known, and the calculation means (16) are designed to calculate trajectory data for use by the at least one additional system (30, 31; 130, 131). The tracking system (10) of claim 26, wherein
the additional system (30, 31; 130, 131) has at least one, preferably mobile, weapon carrier such as a gun or a rocket launcher. A tracking system (10) according to any one of claims 11 to 27, wherein the search sensor (12) is designed to search its search space for a Search second destination (102) and determine second destination information. The tracking system (10) of any one of claims 11 to 28, wherein the following sensor (14) has filter means which, taking into account the Trajectory data can be preset. The target tracking system (10) of any one of claims 11 to 29, wherein the calculation unit (16) is designed to be system-related Include time delays in the calculation of the trajectory data, to increase the time delays when tracking the follow sensor (14) compensate.

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